eQUEST the QUick Energy Simulation Tool - DOE2.com

eQUEST … the QUick Energy Simulation Tool Imagine a building energy simulation tool comprehensive enough to be useful to ALL design team members, yet ...

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eQUEST … the QUick Energy Simulation Tool Imagine a building energy simulation tool comprehensive enough to be useful to ALL design team members, yet so intuitive ANY design team member could use it, in ANY or ALL design phases, including schematic design. We believe you’ll find that eQUEST is well named because it provides something you’ve been looking for but until now have been unable to find … a sophisticated, yet easy-to-use building energy use analysis tool. With eQUEST, you’ll be able to provide professional-level results in an affordable level of effort. Evaluate today’s newest building technologies … at the speed of tomorrow’s design process eQUEST allows you to perform detailed analysis of today’s state-of-the-art building design technologies using today’s most sophisticated building energy use simulation techniques but without requiring extensive experience in the "art" of building performance modeling. This is accomplished by combining a building creation wizard, an energy efficiency measure (EEM) wizard, and a graphical results display module with a simulation "engine" derived from an advanced version of the DOE-2 building energy use simulation program. Imagine being able to evaluate today’s newest building technologies, at the speed of today's design process. Well… imagine no longer! See for yourself. eQUEST is available for you to download FREE from www.energydesignresources.com. A trusted tool… After two decades of continuous development and enhancement, DOE-2 is the most widely recognized and trusted building energy simulation program available today. eQUEST will guide you through the creation of a detailed DOE-2 building model, allow you to automatically perform parametric simulations of your design alternatives, and provide you with intuitive graphics that highlight the performance of your proposed design alternatives … all within a fraction of the time previously required for professional-level analysis. The Building Creation Wizard gets you going so quickly, it may seem like magic… Sophisticated energy use simulation programs have been in existence for more than two decades. Unfortunately, these programs have always required detailed knowledge of both the ART of building energy use analysis and the SCIENCE of the particular energy analysis program itself. The result has been that only specialists could reliably use the sophisticated simulation programs. The level of effort and associated expense generally meant that simulation analysis occurred only once during the design process, most frequently nearer the end of the process, when the most detailed inputs were available. Such a process was not only expensive… it did little to facilitate collaborative energy efficient design (i.e., involving several design team members) throughout the entire design process (i.e., from schematic through final design).

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eQUEST … the Quick Energy Simulation Tool The Building Creation Wizard acts as an expert modeling advisor… eQUEST 3.0 helps to overcome past barriers to simulation by incorporating two building creation wizards: the Schematic Design Wizard (the “Schematic Wizard”) and the Design Development Wizard (the “DD Wizard”), as well as an Energy Efficiency Measure wizard (the “EEM Wizard”). It’s like having an expert advisor, operating between you and the DOE-2 energy simulation program. Either Wizard will guide you through a series of steps designed to allow you to fully describe the principal energy-related features of your design. The wizards then create a detailed description of the proposed design as required DOE-2. At each step of describing your building design, the wizards provide easy-to-understand choices of component and system options. Schematic Design Wizard Users may elect to begin the building simulation process by using the Schematic Wizard. The sequence of steps the wizard takes you through allows you to describe the building’s architectural features and its heating, ventilating, and air-conditioning (HVAC) equipment. The steps are organized so that the most general project information is requested first (Figure 1), followed by more detailed architectural and HVAC information (Figures 2 and 3).

Figure 1 High-level eQUEST project information: building type (sets many subsequent defaults), weather location, heat/cool source (red fonts are user inputs, green fonts are wizardprovided defaults)

Figure 2 eQUEST building geometry information: use this screen to describe the building footprint and HVAC zoning. This can rely on automatic shapes or user-defined “custom” shapes (see Figure 9)

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eQUEST … the Quick Energy Simulation Tool

Figure 3 eQUEST water-side information: use this screen to describe the central plant primary cooling equipment.

When to use the Schematic Design Wizard? The Schematic Wizard is designed to support the earliest design phase, when information is most limited. Although time may also be limited, with even a little practice, you will find that you can explore the energy impacts of numerous design features in an hour or less. The Schematic Wizard is also well suited for smaller, simpler structures. Other features include the following: Building geometry can rely on predefined generic shapes, or custom user input via a drawing tablet, including importing & tracing DWG plan files. Currently, the Schematic Wizard is limited to one building shell and one footprint, i.e., only one structure with all floors in the structure sharing the same basic footprint shape and thermal zoning pattern. Up to two different types of HVAC systems can be described in any one Schematic Wizard project (e.g., built-up chilled water plus rooftop DX units). There are 60+ HVAC system types to choose from. The description of internal loads relies on generic, code-based activity area types having default lighting and equipment power densities. The user can choose between simple building schedule information using occupied vs. unoccupied times and allowing up to two seasons per year or detailed, hour-by-hour occupancy and equipment usage profiles with more flexible season definitions. Zone assignments for internal loads, schedule, and HVAC system types are simple and schematic in detail. Defaults, categorized by building type, are provided for ALL wizard inputs.

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eQUEST … the Quick Energy Simulation Tool

Design Development Wizard (DD Wizard) The Design Development Wizard (the “DD Wizard”) is designed for later, more detailed design (i.e., during the Design Development phase), when more detailed information is available. It is also better suited for larger, more complicated structures, or for use with more detailed internal loads, schedules, and HVAC system assignment requirements. Users may begin their projects using the DD Wizard, or, if they began their building simulation project using the Schematic Wizard, they can elect at any time to continue their project analysis and development using the DD Wizard, e.g., as more detailed project information becomes available. Other features include the following: The generic and custom drawing capabilities of the DD Wizard work the same as in the Schematic Wizard, however, in the DD Wizard, users can describe multiple building shell components, each with similar or very different geometry, shell properties, and HVAC zoning and/or systems. Separate building shell components may be stacked (e.g., to form setback mid- or high-rise designs), or placed adjacent to one another (e.g., to form separate wings or a campus of separate structures). The same 60+ HVAC system types are available for use in the DD Wizard, however, there is effectively no limit on the number of these different system types that can be used in a single project. The description of internal loads can use generic, code-based activity area types (as in the Schematic Wizard), or users may provide much more detailed, even zone-by-zone, descriptions of internal loads and HVAC system assignments. Building schedule information is in the form of hour-by-hour descriptions of building occupancy and equipment usage profiles. Defaults, categorized by building type, are provided for ALL wizard inputs. Not magic… just intelligent dynamic defaults Both the Schematic and DD Wizards offer advice in the form of "intelligent defaults" for each choice. All wizard inputs have defaults (yes, ALL), however, the most important information is collected first, which is used to refine the defaults for later, more detailed inputs. The experience is intended to be like reading a good newspaper, i.e., the further you read into an article, the more detailed understanding you will gain, however, you can “get the gist” by covering only the first few paragraphs. Similarly, in eQUEST’s wizards, it isn’t necessary to complete every single step in either wizard. If you choose, you can "bail out" of the description process once you are satisfied with the level of detail you have provided. At that point, the wizard provides any missing information using eQUEST’s hierarchical default process.

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eQUEST … the Quick Energy Simulation Tool The Energy-Efficiency Measures (EEM) Wizard helps you quickly, easily, and reliably explore the energy performance of your preferred design alternatives The greatest value that energy simulation can provide to the building design professional is reliable guidance in determining the energy performance of design alternatives. After creating a new building description (i.e., using the Building Wizard), you can launch the EEM Wizard to quickly describe up to nine design alternatives to your “base” building description. You can then automatically simulate any or all of these alternative cases and view the simulation results as either individual or comparative graphs or in a detailed “parametric” tabular report. Using the EEM Wizard, designers can easily “weigh” the energy impacts and tradeoffs of their design options. Building energy performance simulation was never so quick, easy, and reliable.

Figure 4 eQUEST EnergyEfficiency Measures (EEM) Wizard: use this screen to describe energy-related features of design alternatives

Intuitive Graphics Tell the Energy Story Once a simulation has been completed, you visualize the results through a number of graphical formats. Overall building estimated energy use can be seen on an annual or monthly basis. Detailed performance of individual building components may also be examined. Figure 5, for example, shows the monthly electrical and gas consumption for a single building simulation and the fraction of that consumption attributed to each of the end-use categories. Figure 6, on the other hand, provides a pair of comparison graphics with associated tabular results that show the monthly electrical and gas consumption for each of five building EEM simulations. A recently added feature now allows detailed "parametric" processing (Figures 1517), in which you can define a series of detailed design alternatives and run them automatically. A new parametric tabular report details the annual use and savings (both incremental and cumulative), by end use (Figure 7) for both the EEM Wizard and detailed parametrics. By performing multiple simulations on your building design alternatives you can take steps to optimize your design, with respect to energy consumption and operating cost, by viewing the alternative results in side-by-side graphics.

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eQUEST … the Quick Energy Simulation Tool

Figure 5, monthly electrical and gas consumption, by end-use

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eQUEST … the Quick Energy Simulation Tool

Figure 6, monthly electric and gas consumption for 5 simulations

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eQUEST … the Quick Energy Simulation Tool

Figure 7, detailed annual energy use, incremental savings, and cumulative savings for 6 parametric simulations

Figure 8, 3-D view of eQUEST model

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eQUEST … the Quick Energy Simulation Tool Provide as much detail as you like… or as little… With eQUEST, you decide how much detail is appropriate. You can rely on predefined building shapes and automatic HVAC zoning or you can import DWG files and use them to create a project-specific footprint shapes and HVAC zoning.

Kitchen Arts & Technology

Cafeteria

Administration

Library

Figure 9, eQUEST custom drawing screen with DWG file imported

Figure 10 eQUEST building shell, 2-D geometry screen (from eQUEST’s Detailed Interface), showing the completed building footprint and user-defined HVAC zoning. Components in the model are listed in the “tree’ on the left side of the screen

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eQUEST … the Quick Energy Simulation Tool

Figure 11 eQUEST building shell, 3-D geometry screen (from eQUEST’s Detailed Interface). Click on any object (i.e., from the component tree or 2-D or 3-D image) to see detailed inputs. Use the Design Development wizard to define multiple architectural shell and/or HVAC components, then assemble these into a completed project (Figure 12).

Figure 12 eQUEST building shell, 3-D geometry screen (from eQUEST’s Detailed Interface), showing a full campus (the building in Figures 9-11 is seen here in the center of the campus). This example consists of four buildings.

Use eQUEST’s Detailed Interface to explore project architectural and HVAC components in detail. Graphical presentation of project components make navigation intuitive (Figure 13).

Figure 13 eQUEST air-side HVAC screen, showing the same building as in Figure 12.

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eQUEST … the Quick Energy Simulation Tool

Figure 14 eQUEST air-side HVAC screen: Click on any object (i.e., from the component tree or system schematic image) to see detailed inputs. HVAC design inputs (e.g., capacities) left blank tell eQUEST “size these”.

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eQUEST … the Quick Energy Simulation Tool Use the Parametric Run dialog in eQUEST’s Detailed Interface to define detailed parametric runs to explore, in detail, the benefit of selected energy-efficient design features (Figures 15-17). Tabular results are automatically produced showing the incremental and cumulative benefits of your selected design features (Figure 7).

Figure 15 eQUEST’s detailed parametric runs dialog (in eQUEST’s Detailed Interface), showing a series of parametric runs exploring the incremental benefit of selected efficiency design features.

Figure 16 Example component list of eight parametric runs

Figure 17, side-by-side “Grid View” comparison of eQUEST parametric runs

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eQUEST … the Quick Energy Simulation Tool What you’ve been looking for … High-Powered Simulation at the Touch of a Button When you exit the eQUEST wizard, you have a complete building description ready for simulation. eQUEST uses an enhanced, interactive, simulation engine… an advanced derivation of DOE-2, to perform an hourly simulation of the described building for a userselected one-year time period. For each hour of the simulation, heating and/or cooling loads are calculated based on contributions from walls, windows (including detailed shading), people, plug loads, and ventilation air and simulates the performance of fans, pumps, chillers, boilers, and all other energy-consuming building components as they respond to the building environment and controls. During the simulation, the energy use is tabulated for each of the end uses including lighting, general space equipment, heating, cooling, ventilation, and pumping. The simulation "engine" within eQUEST is derived from the latest official version of DOE-2, however, eQUEST's engine extends and expands DOE-2's capabilities in several important ways, including: coupled air-side and water-side simulation, an all-new temperature/pressure/flow-based modular central plant simulation, more sophisticated (i.e., polygon-based) geometry, more dynamic/intelligent defaulting, and faster execution speed. Also, numerous long-standing shortcomings in DOE-2 that have contributed to its limited use by mainstream designers and buildings professionals have been improved. The full capabilities of this enhanced and improved DOE-2-derived engine have been integrated into eQUEST to provide you with detailed and accurate energy use estimates in remarkably little time. Computer Requirements To use eQUEST you need a PC with the following: Windows 95, 98, ME, NT, 2000, or XP (Windows 2000 or XP is recommended), having at least 64 Megabytes of RAM, 100 Megabytes of free hard drive space and a display capable of 800x600 resolution at 256 colors (or greater). You should also have internet access to allow the download of additional weather files and updates to new versions of eQUEST as they become available.

The QUEST Continues… Version 3 of eQUEST provides a very capable tool for building energy use analysis, especially in the early conceptual design phase. Future enhancements to eQUEST are planned to permit even more comprehensive analysis… 1. Building energy code compliance checking (initially: California Title 24, later, ASHRAE 90-1) 2. HVAC-related enhancements that will make eQUEST a powerful and convenient HVAC design tool 3. Informative Q/A building model input and output reports to identify inconsistencies in the inputs and simulated results

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eQUEST … the Quick Energy Simulation Tool

Summary of eQUEST Features and Capabilities eQUEST Availability, Cost, and Technical Support eQUEST is provided FREE by courtesy of the State of California's Energy Design Resources program and is available for you to download from www.energydesignresources.com. Technical support is available via email at [email protected]. For questions/problems regarding eQUEST's interface, contact Scott Criswell at [email protected]. For questions/ problems regarding eQUEST's simulation methodology or results, contact Marlin Addison at [email protected]. Number of Users Approximately 7,000 copies of eQUEST have been downloaded from www.energydesignresources.com, however, it is difficult to estimate what portion of these downloads represent active users. Although the original target audience for eQUEST has been California, e-mail support inquiries have been received from all around the world. General Issues Simulation Engine: eQUEST’s engine is “DOE-2.2”, an advanced derivation of DOE-2, initially developed jointly by Lawrence Berkeley National Laboratory and J.J. Hirsch and Associates, under funding from the U.S. Department of Energy and the Electric Power Research Institute. On-going development of DOE-2-based tools, like eQUEST, is continuing under both public and industry funding. The principal focus of these ongoing efforts has been to make detailed hour-by-hour simulation more reliable and affordable for a broader base of design and buildings professionals. # of unique simulation steps per year: 8760 (i.e., hourly) for up to one year maximum analysis period # of specific day types: eQUEST’s schematic design wizard — 3 for each of two seasons (6 total) eQUEST’s detailed interface — hundreds of day types in up to 52 seasons Types of available weather files: all common long-term average weather files, i.e., TMY, TMY2, TRY, CTZ, CTMY, WYEC, WYEC2. There are 667 of these long-term average weather files, representing approximately 300 North American locations. They are available for free download from www.doe2.com. eQUEST automatically downloads missing weather files via ftp, on-demand (prompts for permission). Many international weather files are also available, including via meteoNorm™ (see http://www.meteotest.ch/en/mn_home?w=ber). Actual weather year data is also usable via the National Climatic Data Center (i.e., most popular NCDC weather file formats are supported, see http://lwf.ncdc.noaa.gov/oa/ncdc.html), as are WeatherMaker™ TMY2 files (used to adjust dry-bulb and wet-bulb temperatures to produce site weather data, see http://www.sbicouncil.org/enTen/weather.html).

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eQUEST … the Quick Energy Simulation Tool Analysis methods Heat Transmission through opaque exterior surfaces: two methods: “delayed” method via conduction transform functions (accounts for mass effects in delayed envelope heat transfer); “quick” method via steady-state UA∆T calculations. Heat Transmission through transparent surfaces: three methods are available: 1) shading coefficient method; 2) a predefined glass library (provides improved solar-optical transmission prediction at obtuse incident angles  user additions to library via Windows 4.1); 3) layer-by-layer method (permits detailed treatment of complex fenestration systems, including profile-angle-dependent slat-type shading devices, internal/external/integral  limited number of windows can be accommodated). Interior sunlight/daylight modeling: DOE-2’s solar heat gain calculations do not provide detailed treatment of solar distribution on interior surfaces (i.e., does not project “sun patches” into a space's interior), rather, relies on user-controlled assignment of the interior distribution of solar gain (e.g., assumes 60% of incoming solar is evenly distributed across the floor, 40% is evenly distributed across remaining interior surfaces). By contrast, DOE-2’s daylighting prediction does provide for detailed tracking of the “direct” daylight component (that portion of the daylight which arrives at the workplane without first bouncing off interior surfaces). The treatment of the “indirect” (the internally reflected) component uses the “split-flux” method which predicts average reflected daylight levels and neglects internal obstructions of complex fenestration/spatial configurations. Space Loads: eQUEST relies on DOE-2’s standard and/or custom weighting factors methods. Coil Loads: now coupled in DOE-2.2 with water-side calculations into the same time step. Water-Side: in DOE-2.2, now based on temperature and flow and very modular (i.e., allows for flexible coupling or assignment of primary and secondary equipment). Design-Day Weather data and schedules of operations: in DOE-2.2, up to three 24-hour design day weather profiles can be user input  none are automatically derived from the user-selected weather file. These 24-hour design weather sequences can be repeated for any number of days to include different solar angles. In eQUEST’s conceptual design wizard, design day conditions are automatically selected for any California climate zone locations, based on weather file selection (Title24 design day conditions). The system types listed on the following page are available from eQUEST’s Conventional HVAC Systems Types of HVAC systems that can be modeled: The system types listed on the following page are available from eQUEST’s Building Creation Wizards (listed by cooling and heating source).

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eQUEST … the Quick Energy Simulation Tool HVAC systems that can be modeled using eQUEST's Building Creation Wizards (shown by cooling/heating source) Cooling Source No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling No Cooling DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils DX Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils CHW Coils Evap Cool Evap Cool Evap Cool Evap Cool Evap Cool Evap Cool

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Heating Source No Heating No Heating Furnace Furnace Elec Resist Elec Resist HW Coils HW Coils HW Coils Baseboards Baseboards Baseboards Baseboards No Heating No Heating No Heating No Heating Furnace Furnace Furnace Elec Resist Elec Resist Elec Resist Elec Resist Elec Resist DX Coils (HP) DX Coils (HP) DX Coils (HP) DX Coils (HP) HW Coils No Heating No Heating No Heating No Heating No Heating No Heating No Heating Elec Resist Elec Resist Elec Resist Elec Resist Elec Resist Elec Resist Elec Resist HW Coils HW Coils HW Coils HW Coils HW Coils HW Coils HW Coils HW Coils No Heating No Heating Furnace Furnace Elec Resist Elec Resist

System Type - none Unit Ventilator (no heating or cooling) Gas or Fuel Furnace with zone ventilation Gas or Fuel Furnace with NO zone ventilation Electric Furnace with zone ventilation Electric Furnace with NO zone ventilation Hot Water Furnace with zone ventilation Hot Water Furnace with NO zone ventilation 2-Pipe Fan Coils (heating only) Electric Baseboards (only) with zone ventilation Electric Baseboards (only) with NO zone ventilation Hot Water Baseboards (only) with zone ventilation Hot Water Baseboards (only) with NO zone ventilation Packaged Single Zone DX (no heating) Split System Single Zone DX (no heating) Packaged Terminal AC (no heating) Packaged VAV (no heating) Packaged Single Zone DX with Furnace Split System Single Zone DX with Furnace Packaged Multizone with Furnace Packaged Single Zone DX with Elec Resist Heat Split System Single Zone DX with Elec Resist Heat Packaged Terminal AC with Elec Resist Heat Packaged VAV with Elec Resist Reheat Packaged Multizone with Elec Resist Heat Packaged Single Zone Heat Pump Split System Single Zone Heat Pump Packaged Terminal Heat Pump Water-Source Heat Pump Packaged VAV with Hot Water Reheat Standard VAV (no reheat) Parallel Fan-Powered VAV (no reheat) Series Fan-Powered VAV (no reheat) Single Zone Air Handler (cooling only) 2-Pipe Fan Coils (cooling only) Multizone Air Handler (cooling only) Single Fan Dual Duct (no heating) Parallel Fan-Powered VAV (elec reheat) Standard VAV (elec reheat) Series Fan-Powered VAV (elec reheat) Single Zone Air Handler (elec heat) Reheat Fan System (elec reheat) Multizone Air Handler (elec heat) Dual Duct Air Handler (elec heat) Parallel Fan-Powered VAV (hot water reheat) Standard VAV (hot water reheat) Series Fan-Powered VAV (hot water reheat) Single Zone Air Handler (hot water heat) Reheat Fan System (hot water reheat) 4-Pipe Fan Coils (hot water reheat) Multizone Air Handler (hot water heat) Dual Duct Air Handler (hot water heat) Indirect/Direct Evaporative Cooler (no heat) Direct Evaporative Cooler (no heat) Indirect/Direct Evaporative Cooler (furnace heat) Direct Evaporative Cooler (furnace heat) Indirect/Direct Evaporative Cooler (electric heat) Direct Evaporative Cooler (electric heat)

eQUEST … the Quick Energy Simulation Tool Special HVAC Systems Ground-Source Heat Pumps: these can be directly modeled using eQUEST’s detailed interface, and includes a large variety of ground coupling configurations, e.g., vertical well, horizontal field, “slinky”. Dual-Fuel Cooling Plants: these can be directly modeled using eQUEST’s detailed interface, including preferential loading of base equipment. Primary/Secondary chilled water distribution systems: DOE-2.2’s temperature and flow-based calculations make it much better suited than was DOE-2.1E for modeling primary/secondary distribution systems. Up to twenty secondary loops can be connected to a primary loop. Currently, primary equipment cannot be connected directly to secondary loops. Variable Flow primary distribution systems: as above, DOE-2.2’s temperature and flow-based calculations make it much better suited than was DOE-2.1E for modeling variable flow distribution systems. Dual-Fan Dual-Duct VAV systems: dual-fan dual-duct and multi-zone systems are available in eQUEST. Natural Ventilation: natural ventilation is available in eQUEST via the detailed interface, only for single duct DX systems. The calculation uses the ShermanGrimsrud algorithm. Note that this does not include any mass transport (i.e., CFD), rather, it is an energy transfer algorithm only. Custom Performance Curves: custom equipment performance curves can be modeled in eQUEST’s detailed interface. The user can either specify coefficients or curve data points (up to third order polynomials). Currently, no graphics are provided to illustrate or check the curves. Cogeneration: a wide variety of cogeneration schemes and equipment can be modeled using DOE-2.2 (accessed via eQUEST's detailed interface). These include Photovoltaics (see below) and sell back. Thermal Energy Storage: eQUEST’s TES model is best suited for empty tank chilled water tank systems. Ice TES can also be modeled. Stratified tank chilled water tank systems require significant user judgment. Underfloor Air Distribution: Underfloor systems can be modeled reasonably well by advanced eQUEST users (i.e., requires significant user judgement and some advanced program features). To the extent that underfloor systems rely on displacement ventilation for their energy performance, eQUEST’s DOE-2 loads calculations will be unable to predict the adequacy of the displacement ventilation scheme using first principles. Rather, significant user judgment will be required to model the more-or-less direct transfer of heat gain from lights, people, equipment, and solar to the unoccupied (stratified) or return air mass via convective plumes. Fortunately, the assumed split of heat gains between the occupied and unoccupied air mass can be “expressionized” in eQUEST, i.e., input using dynamic formulas rather than static numbers  this allows the user to conveniently bound the performance of the proposed underfloor displacement system by varying key system characteristics. While the thermal loss from the underfloor plenum can be approximated using DOE-2.2’s duct loss modeling, the effect of any “coolth” charge to the underfloor mass is not accounted for. Contact the eQUEST developers for a paper describing the literature, data sources and suggested approach to modeling underfloor air distribution systems.

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eQUEST … the Quick Energy Simulation Tool New Special System Features Photovoltaics: a PV algorithm has recently been added to DOE-2.2. Although no interface has been provided yet in eQUEST, the PV keywords are accessible via BDL/DOS. Energy Recovery Ventilators: a wide variety of ERV configurations and options have recently been added to DOE-2.2. No interface has been provided yet in eQUEST. The ERV keywords are accessible via BDL/DOS. Ice Rinks and Industrial Refrigeration Systems: the ability to model complex modular configurations for refrigeration systems and ice rinks has recently been added to DOE-2.2. No interface has been provided yet in eQUEST for the new refrigeration-related keywords. These keywords are accessible via BDL/DOS. Notable DOE-2 HVAC Omissions Solar Thermal: currently, there is no capability to model solar thermal systems in eQUEST or DOE-2.2. Vertical Self-Contained Fan-Powered VAV: currently, there is no capability to model fan-powered VAV systems having DX cooling coils in eQUEST or DOE-2.2. Funding is in place to model this system. Completion of this addition is expected by the end of 2001. Steam Loops: DOE-2 has never been able to directly model steam distribution systems. HW distribution systems are used to approximate steam systems. Plate-and-frame economizers: DOE-2 has never included the ability to model plate-and-frame type water-side economizers, either series or parallel configurations. Two or more HVAC systems serving the same zone: DOE-2 has never been able to model the use of two or more systems to provide cooling or heating service to the same zone. The only exception is baseboard heating combined with ambient heating (e.g., reheat coils). Comfort-controlled radiant cooling or heating systems: DOE-2 has never been able to model radiant systems other than those whose control is via a standard drybulb thermostat. Water-Use and Emissions: DOE-2.2 does not currently include either water use calculations or emissions calculations. Emissions calculations are anticipated in the near future. Controls DOE-2 has always assumed “perfect” control where capacity and operations permit. This makes it difficult to approximate the behavior of typical “real world” control, e.g., poorly maintained or calibrated controls, sticking valves or linkages, failed actuators, etc. Indirectly, DOE-2’s “perfect” control tends to be a better approximation of PID/DDC control than pneumatic controls. Daylighting Controls: three types of daylighting controllers are provided in both eQUEST’s wizard and detailed interface: stepped, dimming, dimming/off. Demand Limiting: demand limiting capabilities are available via eQUEST's detailed interface. Given the coupling between the air-side and water-side calculations in DOE-2.2, the affect of air-side resets are passed on to chilled water resets and the affect on space temperature is determined.

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eQUEST … the Quick Energy Simulation Tool Controls (continued) Window Shades: manually or automatically operated window shades can be modeled from eQUEST’s detailed interface. Triggers include transmitted solar and estimated visual discomfort glare. Night Venting: night venting can be modeled directly from eQUEST’s detailed interface. One-Hour time step: The fixed one-hour time step that has always been built into DOE-2 makes it difficult to model many control system effects. Optimum Start / Morning Warm-up: Optimum start is provided directly in eQUEST’s detailed interface, however, DOE-2’s fixed one-hour time step makes this a rather “blunt” instrument to predict the benefit of optimum start. Morning warm-up outside air strategies can be well modeled from eQUEST’s detailed interface. This can also be well integrated with economizer actions. Utility Rates DOE-2 has long been able to model a wide variety of utility rates. Rate features that can be easily accommodated include: inclined or declining block rates, hours use (variable block) rates, time-of-use rates, ratchets, rate limiters, customer service/meter charges, taxes/surcharges, and fuel adjustments. Rate qualifiers can also be modeled which can select among several available rates, the one that applies, based on peak kW or energy. It should be comparatively rare that a DOE-2.2 user would encounter a rate feature that cannot adequately be modeled. Typically, this tends to be specialized “IF then” tests built into a rate, e.g., offpeak kW is free unless the on-peak kW is less than 25% of the off-peak kW, in which case some charge applies per off-peak kW. NOTE: currently eQUEST only comes with California utility rates predefined. Users can add their own custom rates, however, this is not a simple undertaking (i.e., requires a user to prepare a text file containing DOE-2 BDL commands describing the custom utility rate — user documentation is provided). Energy Code Compliance Funding has been allocated to add California Title 24 compliance analysis to eQUEST. Work on this is nearing completion. Once completed, this will permit eQUEST users to certify their building designs for Title 24 compliance. eQUEST will produce the necessary submission forms. Additionally, eQUEST will be able to automatically complete compliance runs as part of general parametric energy analyses, e.g., Savings By Design analysis. eQUEST implements its compliance capabilities via external rule sets, driven by a rule processor. It is expected that this capability will be extended to include other codes, such as ASHRAE 90.1. Interoperability eQUEST has recently added DWG import capabilities. This provides users with the ability to import DWG files, then use them as a guide to “trace” the shape of the building footprint and zoning in a drawing module.

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